Uplink noise minimization

ABSTRACT

A system comprising circuitry configured to: communicate with a base station; and adjust an uplink gain applied to uplink signals communicated from the system to the base station based on an evaluation of (1) a noise contribution from the system that is presented to the base station and (2) a receive noise floor for the base station.

CROSS-REFERENCE TO RELATED APPLICATIONS

This Application is a continuation of U.S. application Ser. No.15/483,771, filed Apr. 10, 2017 and entitled “UPLINK NOISEMINIMIZATION”, which is a continuation of U.S. application Ser. No.15/201,069, filed Jul. 1, 2016 and entitled “UPLINK NOISE MINIMIZATION”(which issued as U.S. Pat. No. 9,622,199), which is a continuation ofU.S. application Ser. No. 14/874,891, filed Oct. 5, 2015 and entitled“UPLINK NOISE MINIMIZATION” (which issued as U.S. Pat. No. 9,386,546),which is a continuation of U.S. application Ser. No. 13/705,814, filedDec. 5, 2012 and entitled “UPLINK NOISE MINIMIZATION” (which issued asU.S. Pat. No. 9,155,055), which is a continuation of and claims priorityto International Application No. PCT/US2011/039592, filed Jun. 8, 2011and entitled “UPLINK NOISE MINIMIZATION”, which in turn claims priorityto U.S. Provisional Patent Application Ser. No. 61/352,851 filed Jun. 9,2010 and entitled “UPLINK NOISE MINIMIZATION”, each of the applicationsand disclosures of which are incorporated herein by reference in theirentireties.

FIELD OF THE INVENTION

The present invention relates generally to signal repeating systems,such as repeaters or distributed antenna systems, for wirelesscommunications.

BACKGROUND OF THE INVENTION

In existing wireless technologies, signal repeating devices and systems,such as repeaters or distributed antenna systems (“DAS”), are used toextend the coverage of an overall wireless system beyond the range oftraditional base stations. For example, an overall cellular or wirelesscommunication system may consist of a plurality of base transceiverstations (“BTS”) or base stations that communicate with each other andwith mobile user devices, such as cellular mobile phones, to provide adefined coverage area. In such coverage areas, there are often smallergeographical areas that have very low signal coverage, as provided byone or more of the base stations. For example, such areas of low signalcoverage may be within buildings or in areas that are otherwiseobstructed, such as by terrain features or man-made structures. Ratherthan simply implementing another costly and large base station in thearea to provide coverage in such low signal areas, repeaters anddistributed antenna systems are often utilized.

The distributed antenna system receives downlink signals from one ormore donor base stations and distributes those signals via cable, suchas fiber optics, coaxial cables, or copper twisted pair cable,throughout a building or other coverage area. At designated accesspoints in the system, remote units amplify the downlink signals andtransmit them to user equipment, such as mobile phones over radiatingantennas. At those same access points, uplink signals are received bythe remote units from mobile users, and the uplink signals areamplified, filtered and sent back through the distributed antennasystem, where they are summed together and transmitted to the donor basestation.

Many challenges exist with contemporary distributed antenna systems, oneof which is maintaining a suitable noise floor in the system. Summing ofthe uplink signals from the various multiple remote units cumulativelyadds the noise floors of each of the remote units. For example, a largesystem with 100 remote units summed together may raise the noise floorapproximately 20 dB relative to the noise floor of a single remote unit.In order to compensate for the rise in the noise floor of the system,the mobile units interacting through the system must increase theirtransmit power. Based on the above example of a 20 dB rise in the noisefloor, the mobile units will therefore need to increase their power by20 dB in order to maintain a minimum acceptable carrier to noise ratio(C/N) coming out of the distributed antenna system. Since mobile unitshave a limited amount of transmit power that they can generate, thisrequired increase in transmit power for the repeating system ultimatelydecreases range of the mobiles or the maximum distance from the remoteunit of the distributed antenna system that the mobile unit caneffectively communicate.

An additional challenge caused by the large noise floor rise is basestation desensitization. Depending on path loss to the base station fromthe remote system, the noise floor contributed from the distributedantenna system could arrive at the base station at a higher level thanthe base station's own noise floor. When this occurs, the base stationwill be desensitized, potentially resulting in a shrinking coverage areafor the base station. To assist in preventing the loss of coverage area,the uplink gain of the distributed antenna system should be set to afairly low value to assure that the received noise floor from thedistributed antenna system arrives at a level below the base station'sown noise floor. For example, the distributed antenna system gain mightbe set such that the distributed antenna system noise floor arrives atthe base station approximately 10 dB below the base stations own noisefloor. In this situation, adding the distributed antenna system noise tothe base station noise will result in only about a 0.4 dB rise in theoverall floor noise at the base station receiver.

From the perspective of the mobile unit in the distributed antennasystem having 100 remotes units, a 20 dB rise in the noise floor, asdescribed above, requires the mobile units to increase their transmitpower by 20 dB. The mobile units must also increase their power another10.4 dB to overcome the base station noise floor which is 10.4 dB abovethe distributed antenna system noise floor. This further reduces thedistance from the respective remote unit that mobile units cancommunicate.

To improve this situation, a squelch or muting can be applied to theuplink of any remote unit that has no traffic. This generally assists indecreasing the distributed antenna system noise rise and, for theexample above, may also assist in decreasing the 0.4 dB noise rise atthe base station. However, the mobile units can only decrease theirtransmit power a few tenths of a dB (0.4 dB max for the above example)in order to maintain the same C/N ratio at the base station. Therefore,while muting one or more remotes do assist in reducing base stationdesensitization slightly, it does not allow the mobile unit tosignificantly decrease its transmit power. Therefore, such a featuredoes not address the problems noted above or significantly increase therange of a distributed antenna system remote unit.

Embodiments of the present invention address these and other challengesin the prior art as discussed further below, and provide a significantadvantage over contemporary distributed antenna systems having a largenumber of remote units.

SUMMARY OF THE INVENTION

Embodiments of the invention address the need in the art by providing amethod of gain adjustment in a distributed antenna system having amaster unit and a plurality of remote units. A noise condition of thedistributed antenna system is monitored, and the uplink gain within thedistributed antenna system that is applied to uplink signals to a basestation, is dynamically adjusted based on the monitored noise condition.In one embodiment, the monitoring of a noise condition includesmonitoring one or more remote units of the plurality of remote units anddetermining if the remote unit is active status or mute status. Theuplink gain is dynamically adjusted by increasing the uplink gain inresponse to a decrease in the number of remote units that are activestatus, and decreasing the uplink gain in response to an increase in thenumber of remote units that are active status.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate embodiments of the invention and,together with a general description of the invention given above, andthe detailed description given below, serve to explain the invention.

FIG. 1 is a schematic diagram of an exemplary distributed antennasystem.

FIG. 2A is a schematic diagram of an exemplary distributed antennasystem with multiple remote units consistent with embodiments of theinvention.

FIG. 2B is a schematic diagram of an alternate exemplary distributedantenna system with distribution units and multiple remote unitsconsistent with embodiments of the invention.

FIG. 3 is a schematic diagram of an embodiment of a remote unit of a DASsystem consistent with the invention.

FIG. 3A is a schematic diagram of an alternative embodiment of a remoteunit of a DAS system consistent with the invention.

FIG. 3B is a schematic diagram of another alternative embodiment of aremote unit of a DAS system, consistent with the invention.

FIG. 4 is a schematic diagram of an alternative embodiment of a remoteunit of a DAS system consistent with the invention.

FIG. 4A is a schematic diagram of an alternative embodiment of a remoteunit of a DAS system consistent with the invention.

FIG. 5 is a schematic diagram of a portion of a remote unit consistentwith the invention.

It should be understood that the appended drawings are not necessarilyto scale, presenting a somewhat simplified representation of variousfeatures illustrative of the basic principles of the invention. Thespecific design features of the sequence of operations as disclosedherein, including, for example, specific dimensions, orientations,locations, and shapes of various illustrated components, will bedetermined in part by the particular intended application and useenvironment. Certain features of the illustrated embodiments have beenenlarged or distorted relative to others to facilitate visualization andclear understanding. In particular, thin features may be thickened, forexample, for clarity or illustration.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is directed to a method and apparatus forcontrolling uplink signal power in a distributed antenna system that hasa master unit and a plurality of remote units. The master unit iscoupled with a base station, and the remote units are coupled with themaster unit. The invention includes monitoring of a noise condition of adistributed antenna system, and dynamically adjusting an uplink gainwithin the distributed antenna system, that is applied to uplink signalsto a base station, based upon the monitored noise condition. In oneexemplary embodiment, the number of active status remote units isdetermined, and the uplink gain is dynamically adjusted by increasingthe uplink gain in response to a decrease in the number of remote unitsthat are active status, and decreasing the uplink gain in response to anincrease in the number of remote units that are active status. Otherembodiments of the invention, as set forth herein, are also contemplatedin the invention.

An exemplary distributed antenna system (DAS) 10 for implementing theinvention may be appropriately coupled to one or more base transceiverstations (BTS), such as BTS 12 in a wired 13 or wireless 15 fashion asillustrated in the in FIG. 1. The distributed antenna system 10 might beincorporated into a building environment or other suitable environmentand will generally include a number of remote antenna units or remoteunits 14 that are distributed in the environment to provide wirelesssignal coverage within a specific service area of the DAS 10. In thatway, the remote antenna units 14 service a number of different mobileunits/devices or other user equipment (UE) devices 16 operating in theenvironment of the DAS 10. Generally, each remote antenna unit 14typically includes one or more antennas 18 and suitable electronics 20.A simple antenna 18 is illustrated in the figures. However, theinvention is equally applicable in distributed antenna systems usingmultiple input multiple out (MIMO) technology. Therefore, in such a MIMOsystem, element 18 would be reflective of multiple antennas at theremote units.

Remote antenna units 14 are coupled generally to one or more masterunits 22, which combine and process the signals from the multiple remoteantenna units 14 to interface appropriately with the BTS 12. The masterunit interface to the BTS 12 may be wireless or in a wired arrangement.A system controller 24 controls the operation of each of the masterunits 22 for handling and processing the various signals 26 associatedwith the remote antenna units 14. The signals 26 associated with theremote antenna units 14 are reflective of uplink and downlink signals ofthe DAS 10 for communicating with mobile units 16. Such a DAS 10 mayincorporate any number of remote antenna units 14 and master units 22,and thus, would not be limited to the illustrated example shown in FIG.1.

Furthermore, the DAS might implement one or more extension units ordistribution (See FIG. 2B) or other units which couple to various remoteunits 14 to combine or aggregate signals from the remote units beforethey are passed to the master units 22. Therefore, the present inventionis not limited to direct links between the master units 22 and remoteunits 14 but rather is also applicable to systems using other elementsthat combine signals from the remote units 14 and are coupled betweenthe master units 22 and remote units 14.

Embodiments of the invention optimize the performance of the distributedantenna system having many remote units such as DAS 10 in FIG. 1. Asdiscussed above, the practice of muting one or more of the remote unitsassists in lowering a noise floor of the DAS 10. However, the muting ofthe remote units does not necessarily allow the mobile devices 16 tosignificantly reduce their power. Nor does the practice of remote unitmuting improve the remote unit's 14 coverage area. Embodiments of theinvention dynamically change or adjust an uplink gain of the DAS 10 orsome portion of the DAS 10 as a function of the change or variation in anoise condition in the DAS, such as a change or variation in the DAS 10noise floor. Various different conditions may cause a drop in the noisefloor of the DAS. For example, a drop in the noise floor may be due tomuting of the remote units in some embodiments. In other embodiments anoise floor drop may result from squelching or muting unused frequencybands or unused frequency subbands in one or more remote units 14.

In accordance with one embodiment of the invention for a particularincremental change in the noise condition, the uplink gain isdynamically and incrementally adjusted. For example, for each 1 dBdecrease in the DAS 10 noise floor, the uplink gain for the DAS may bedynamically increased by 1 dB. Increasing uplink gain, in accordancewith the invention, assists the mobile units in being able to reducetheir transmit power by the same amount in dB as the uplink gainincreases. Increasing the uplink gain is also beneficial in increasing areceive range of the remote units.

FIG. 2A illustrates an exemplary signal repeating system that mayincorporate embodiments of the invention. Specifically, FIG. 2Aillustrates a schematic diagram for an exemplary distributed antennasystem 10. Similar to the exemplary system in FIG. 1, the DAS 10 may beappropriately coupled to one or more base stations, such as base station12, in a wired or wireless fashion. The DAS may include a number ofremote antenna units 14, which are distributed in an environment toprovide signal coverage within a service area of the DAS 10. In thatway, the remote antenna units 14 service a number of different mobiledevices 16 operating in the environment of the DAS 10. Remote antennaunits 14 are generally coupled to one or more master units (“MU”) 22,which combine and process the signals from the remote antenna units 14to interface appropriately with the base station 12.

FIG. 2B illustrates an alternate embodiment of a DAS 10 including one ormore distribution units that interface with the remote units 14. Asshown in FIG. 2B, one or more distribution units 28 (“DU”) may becoupled between remote units 14 and the master unit 22. The distributionunit 28 is generally responsible for summing the signals in the uplinkdirection (“UL”) from the plurality of mobile units 16 that interfacewith remote units 14. The signals 26 of the remote antenna units 14 arereflective of the uplink and downlink signals of the DAS 10 forcommunicating with the mobile units 16. The uplink and downlink signalsare transceived between the remote units 14, the distribution units 28,and the master units 22 over suitable transmission media 30, 32, such asoptical fiber, coaxial cable, and/or twisted pair cables, though otherwired or wireless transmission media may also be used in accordance withthe invention. While a single master unit 22 is shown in FIGS. 2A and2B, embodiments of the invention may incorporate any number of remoteantenna units 14, distribution units 28, and/or master units 22, andthus, would not be limited to the illustrated examples shown in FIGS. 2Aand 2B.

Each active remote unit 14 that is operating, such as by transceivingsignals with a mobile unit 16 and handling signal traffic, contributesto the overall noise condition and floor of the DAS 10. Such a remoteunit is considered active or in “active” status. Muting or inactivatinga remote unit 14 decreases the DAS 10 total noise floor by someincremental amount, which may be a known increment. The remote is thenin “mute” status of inactive status. The remote units pass betweenactive status and mute status, depending on the signal traffic.Conversely, use of the remote unit 14 to pass uplink signals to themaster unit 22 increases the DAS 10 total noise floor generally by thesame increment. To assist the master unit 22 in determining the numberof active remote units 14, the remote unit 14 is configured to report amute status or active status to the master unit 22, such as through astatus signal. In other embodiments, instead of reporting a mute statusof a remote unit, the mute status may be determined based on a level ofdata received from a remote unit 14 at the master unit 22 or even at thedistribution unit 28. In one embodiment of the invention, the decisionon whether to consider a remote in mute or active status may generallybe based on detection of uplink signals from mobile units 16. Forexample, the received signals from mobile devices 16 and traffictherefrom may be detected using RSSI based detection techniques or otherdetection techniques as set out further below.

Each master unit 22 attempts to maintain a target noise floor orcondition for the DAS system such that the target noise floor for themaster unit 22 and DAS system 10 plus a path loss from the master unit22 to the base station 12, is lower than or below the noise floor of thebase station 12 by a predetermined threshold amount (e.g. 10 dB). Themaster unit 22 noise floor perceived by the base station is affected byand may be determined from the gain that is applied by the master unit22, in addition to the overall DAS 10 noise floor. As explained above,the overall DAS 10 noise floor is affected by and may be determined bythe number of active status remote units 14 transmitting uplink signalsfrom one or more mobile units 16 in the active area or space of the DAS10.

An initial uplink gain level or baseline uplink gain of the distributedantenna system 10 may be determined by the master unit 22. That baselineuplink gain might be confirmed during setup of the DAS 10 and may bebased on the number of remote units 14 in the system as well as the pathloss back to the base station 12 from the master unit 22. Any changes tothe gain applied by the master unit 22 to the uplink signals are thenconstrained by the master unit 22 target noise floor. The DAS gain ischosen to put the DAS noise floor below the BTS receive noise floor bysome pre-determined threshold amount, such as 10 dB, as noted above.This baseline uplink gain is then used when all the remote units areactive status (or unmuted) and operating at full gain. Then, the masterunit, or some other unit where the remote units are summed together inaccordance with the invention, has the ability to increase the uplinkgain above the baseline level. Based on a monitored noise condition ofthe DAS 10, such as based on the number of active status or most statusremote units, the invention dynamically adjusts the uplink gain of theDAS 10. In accordance with one aspect of the invention, the master unit22 is able to increase the uplink signal gain that is applied to uplinksignals in response to a decrease in the number of active status remoteunits 14 that are determined by the DAS system.

Any increase in signal gain would be under the constraint of an upperlimit for the gain that may be based on the master unit 22 target noisefloor. For example, the upper limit could be based on a selected gainfor the case of a single remote that is active status or some othervalue. The upper limit might also be based on the downlink gain of theDAS. The master unit 22 also decreases the uplink signal gain applied touplink signals in response to an increase in the number of active statusremote units 14. Such a gain decrease is also constrained by the masterunit 22 target noise floor. Thus, the master unit 22 may determine thenumber of active status (e.g., non-muted) remote units 14 based onstatus updates (e.g., muted or non-muted) received from each remote unit14 or other parameters. For example, the number of active remote unitsmight be determined by monitoring a parameter, including the datareceived from each respective remote unit 14. From this determination,the master unit dynamically adjusts the uplink gain to the base station,keeping the overall noise from both the DAS 10 and master unit 22 at ornear the target noise floor for the overall DAS. The uplink gain isdynamically increased and decreased as remotes go in and out of mutestatus (i.e., squelching).

In some embodiments of the invention, detecting signals from the mobileunits 16 determining if the remote is in active status or muted statusmay take place in either the remote unit 14 or in the distribution unit28, before the signals are combined. Generally, the determination of amuted or active/non-muted status will take place prior to combining allof the signals from the multiple remote units. In one embodiment, aMUTE_STATUS (e.g., mute or active/non-muted) signal may then be reportedupstream to the master unit 22 so that the master unit 22 candynamically adjust the uplink gain. The uplink gain may then be set as afunction of the number of remote units 14 that are mute status orconversely that are active status.

FIG. 3 illustrates a schematic diagram representing an exemplaryembodiment of a remote unit 14 utilizing RSSI-based monitoring andmuting in accordance with one embodiment of the invention. In thisembodiment, the received analog signal, such as an uplink signal from amobile unit, is down-converted with appropriate electronics 34 anddigitized by an analog to digital converter (“A/D”) 36. The uplinksignals may then be directed to the master unit 22 or a distributionunit 28 for further processing. For the purpose of detecting an activestatus remote unit, the digitized signal may then be filtered with aband or channel filter 38, and then be directed to a detection unit 39.The detection unit may include an exponential averager circuit 40 andcomparator circuit 44. The signal is averaged using exponential averagercircuit 40. A time constant 42 input to the averager circuit 40 may beadjustable and utilized to change how quickly the averager circuit 40responds to fast signal changes. The output of the averager circuit 40is directed to a comparator circuit 44 where it is compared to apredetermined threshold level 46 to determine whether signal trafficfrom a mobile unit 16 is present in the bandwidth of the filter 38. Ifthe power level of the averaged digital signal 41 is above the thresholdlevel 46, the digital uplink signal 37 may be passed at full gainupstream to either a distribution unit 28 or directly to the master unit22. If, however, the power level of the averaged signal 41 is less thanthe threshold level 46, a muting circuit 48 is employed to substantiallyattenuate the digital uplink signal in order to reduce the noise signalpower that is sent to the master unit 22 that will ultimately increasethe noise floor at the DAS 10 and the base station 12.

The muting circuit 48 may be controlled by an output status signal 50(MUTE_STATUS) from the detection circuit, such as from the comparatorcircuit. The level of the MUTE_STATUS signal will thus determine if theremote unit is active status or mute status and if the uplink signalsfrom the remote unit 14 are muted or left unmuted. In one embodiment ofthe invention, the status signal 50 for the muting circuit 48 isreported to the master unit 22. The status determination can occur inthe remote unit or a distribution unit, and generally will occur beforethe signals are combined in the uplink direction. The master unit 22uses this status signal 50, in one embodiment, to determine the numberof remote units 14 that are active status or mute status. In accordancewith the invention, the master unit 22 then further determines anappropriate uplink gain based on the number of active or muted remoteunits 14.

Other embodiments of the invention do not utilize RSSI detection and maymonitor a particular uplink band or channel parameter for activity frommobile units 16 to determine whether or not to mute the uplink signalfrom the remote unit 14 based on that activity. For example, in a CDMAsystem, code detection or pilot signal detection might be used to detectactivity and thus, active status, in a remote unit. Still otherembodiments employ other methods of detecting uplink signals from themobile units 16 either in the remote unit 14 itself, or furtherupstream, such as at the distribution unit 28 or even at the master unit22. The uplink gain is then actively controlled based on the number ofactive remote units or muted remote units.

As noted, the baseline uplink gain for the master unit 22 may bedetermined during system setup of the DAS 10 based on the number ofremote units 14 in the system and the path loss from the master unit 22to the donor base station 12. As described above, the uplink gain ischosen such that the DAS 10 noise floor is below the receive noise floorof the base station 12 by some predetermined amount, for example,approximately 10 dB. This baseline uplink gain may then be used by themaster unit 22 when all the remote units 14 of the system are activestatus and unmuted and operating at full gain.

As one or more remote units 14 are selectively muted or otherwise goinactive, the master unit 22 may dynamically increase the uplink gain bydiscrete amounts. In one embodiment of the invention, the discreteamount of the increase in uplink gain is reflective of or in relation tothe amount of decrease in the noise level from the muting of the one ormore mute status remote units. For example, the uplink gain might bedynamically increased by increments that correspond to the specificnoise level decrease increments for each remote unit that is muted orthat goes inactive. In another embodiment, some other increment fordynamically increasing the gain might be implemented.

In another embodiment, the gain might be dynamically adjusted based onthe actual number of remote units or groups of remote units that aremuted or mute status. For example, if 1-10 remote units are muted, thegain might be increased by one predetermined increment; if 11-20 aremuted, the gain might be increased by another higher increment, and soforth. The uplink gain will be dynamically increased above the baselinelevel to a maximum level. As noted, the maximum gain level will be setat a level that still attempts to keep the DAS 10 noise floor below thereceive noise floor of the base station 12 by some predetermined amount.The upper limit for the uplink gain increase may be determined for thecase of a single active status remote unit 14 transmitting at full gainwith all of the other remote units 14 muted or mute status.Alternatively, the upper limit for the uplink gain may be determinedbased on some other value such as, for example, the downlink gain, asnoted. As such, the uplink gain from the master unit 22 dynamicallyincreases and decreases as the remote units 14 are muted and unmuted inaccordance with one aspect of the invention.

Remote units 14 implemented in the invention may cover one or morefrequency bands, which may or may not be in use at a particular time.However, activity in only one of the specific bands for a remote unitmay be sufficient to unmute a remote unit 14. This will then contributeto the noise related to all of the bands, even when many of thefrequency bands are unused at a particular time. Embodiments of theinvention address this situation by muting or squelching individualbands within a remote unit 14. For example, remote unit 14 may covermultiple frequency bands (1-M) 52, 54, and 56 as seen in FIG. 4. Some ofthe bands 52, 54, 56 in the remote unit 14 may be selectively mutedwhile other bands are not. Additionally, within each band there can bevarious subbands defined 58-80, as illustrated in FIG. 4A. In someembodiments, selective muting may occur at the subband level. Thus, inaddition to adjusting the DAS uplink gain based on a remote unit 14 as awhole, the uplink gain may also alternatively be dynamically varied fromone band to the next and/or from one subband to the next based on themute status or active status of each remote unit with respect to theparticular band or subband. In some embodiments, the subband bandwidthmay be a single channel wide (e.g. for a GSM channel, the channelbandwidth is approximately 200 kHz, for UMTS the channel bandwidth isapproximately 5 MHz). In other embodiments, a subband may encompassmultiple channels or other bandwidths.

As illustrated in FIG. 4A, band 52 includes subbands 58, 60, 62, 64;band 54 includes subbands 66, 68, 70, 72; band 56 includes subbands 74,76, 78, 80. Signals for each band 52, 54, 56 may be received atrespective antennas 18 a, 18 b, 18 c of the remote unit 14, downconverted with appropriate electronics 34 a-c and converted to digitalwith A/D converters 36 a-c. In some embodiments, depending upon thebands and subbands, various bands/subbands might share a single antenna.Therefore, the invention is not limited to having a dedicated antennafor each band or subband. For the purpose of illustrating one embodimentof the invention; FIGS. 4 and 4A illustrate a specific antenna 18 a-c,for each noted band or group of subbands. As illustrated in FIG. 5, thecircuits 58, 60, 62 and 64 defining the subbands of band 52 includemixer currents 82, 84, 86 and subband filters 88, 90, 92 that separatethe full band 52 into smaller subband widths 58, 60, 62, 64. Detectionunits 94, 96, 98 may be configured to only detect mobile unit 16activity within each corresponding subband 58, 60, 64 bandwidth.Detection units 94, 96, 98, for example, might be configured similar tothe detection unit 39 from the circuit, as shown in FIG. 3. As withembodiments above, the detection units 94, 96, 98 may compare thereceived uplink signals to a predetermined respective threshold signallevel 100, 102, 104 to determine whether a traffic signal from mobileunit 16 is present in the bandwidth of the corresponding subband 58, 60,64. If the signals or power levels within the subband 58, 60, 64 areabove the respective threshold 100, 102, 104, thus indicating uplinktraffic in the subband, the output MUTE_STATUS, 112, 114, 116 of thedetection units 94, 96, 98 indicates that the remote unit signals arenot to be muted (e.g., mute status) but rather, have uplink signals andare, therefore, active status. The respective muting circuits 106, 108,110 are then operated so that the signals may be passed at full gain forthe subband 58, 60, 64 upstream to either a distribution unit 28 ordirectly to the master unit 22. If the uplink signals associated withthe subbands are below the threshold 100, 102, 104, and the remote unitsare mute status, the muting circuits 106, 108, 110 may be utilized tosignificantly attenuate or mute the signals associated with the subbandsand reduce the noise. As noted, the mute status may be simply based uponlack of signal traffic, and may not require or use muting circuits toactually mute or squelch any signals from the remote unit. For example,as shown in FIG. 3B, a specific muting circuit is not implemented.

The MUTE_STATUS signals 112, 114, 116 of each of the subbands 58, 60, 64in each remote unit 14 may also be reported to the master unit 22,similar to the embodiments discussed above. FIG. 5 illustrates circuitryassociated with band 52 and subbands 58, 60 and 64. Similar circuitrymight be implemented for the various other bands 54 and 56 and theirrespective subbands as illustrated in FIGS. 4 and 4A.

In accordance with one embodiment of the invention, the MUTE_STATUSsignal of the various subbands might be forwarded to the distributionunit which determines how many subbands are muted before various of theuplink signals from the remote units are combined to be forwarded to themaster unit. The number of subbands that are muted may then be reportedto the master unit. The master unit 22 may then dynamically adjust theuplink gain associated with the various muted subbands. That uplink gainmay then affect all of the subband signals from the individual remoteunits. In such an embodiment, the master unit would have appropriateuplink gain circuitry that is dynamically adjusted to achieve thedesired increased uplink gain based upon muting one or more of theremote units or one or more of the subbands from a remote unit. As notedabove, the invention might provide an incremental increase in uplinkgain that is reflective of the incremental decrease in noise from aparticularly muted subband. Alternatively, depending upon the number ofsubbands that are muted, the uplink gain might be increased by someother appropriate increment. Accordingly, the invention is not limitedto the specific dynamic adjustment increments for the uplink gain basedupon the mute status or active status of one or more remote units or oneor more subbands of a remote unit.

In an alternative embodiment of the invention, the dynamic adjustment tothe uplink gain may take place in a distribution unit 28 as illustratedin FIG. 2B upon determining the number of remote units and number ofsubbands that are muted, such as, for example, based upon theMUTE_STATUS signal from each remote unit. In such a case, the uplinkgain is dynamically adjusted as noted above, with increases anddecreases based upon active status or mute status or mute status remoteunits.

In a further alternative embodiment of the invention, the dynamicadjustment of the uplink gain may occur in the remote unit.

For example, referring to FIGS. 3A and 3B, remote unit 14 a mightincorporate gain circuitry 49 to individually and dynamically adjust thegain of the uplink signals associated with remote unit 14 a. To thatend, the gain circuitry 49 might be controlled by one or more signals 51indicated in FIG. 3A as UL_GAIN. The UL_GAIN signal(s) 51 may bedirected to the remote unit 14 a from the distribution unit 28 or masterunit 22 in that way, the uplink gain of individual signals from a remoteunit might be affected.

In still another embodiment of the invention directed to a remote unitwhich handles multiple bands or multiple subbands as illustrated inFIGS. 4, 4A and 5, the gain might also be dynamically adjusted at theremote unit. For example, referring to FIG. 4, remote unit 14 mighthandle bands 1-M through appropriate circuitry 52, 54 and 56 forhandling the signals of the respective bands. Gain circuitry 53, 55 and57 associated with the respective bands is utilized to dynamicallyadjust the uplink gain associated with the respective band for theremote unit 14. As such, to provide the dynamic adjustment of a gain,one or more control signals might be directed to the gain circuitry of aremote unit from the distribution unit or master unit. That is, once theMUTE_STATUS of the various remotes and the various bands of the remotesis determined, appropriate control signals may be utilized and directedto a particular remote unit 14 to affect the uplink gain circuitryassociated with one or more bands handled by the remote unit. Referringto FIG. 4, such signal(s) are indicated as UL_GAIN_1, UL_GAIN_2, andUL_GAIN_M, and respectively by reference numerals 59, 61 and 63. In thatway, the uplink gain might be dynamically adjusted individually forcertain bands of a remote unit based upon the number of remote unitsthat are muted or the number of bands that are muted in the DAS.

In still another alternative embodiment of the invention, dynamic gainadjustment might be made for each subband based upon muting conditionsfor the remote units/bands/subbands as noted above. Referring to FIG. 5,the subband circuitry 58, 60, 64 might include respective adjustablegain circuitry 124, 126, 128 as illustrated. Depending upon theMUTE_STATUS of a particular subband, or the total number of subbandsthat are muted in the system, the gain circuitry 124, 126, 128 might bedynamically adjusted to change the uplink gain. For example, based uponthe particular MUTE_STATUS signal, for a particular subband, therespective gain circuitry might be adjusted. As noted above, the dynamicgain adjustment might be made incrementally for each subband that ismuted or might be adjusted based upon the numbers of subbands that aremuted, for example. To that end, appropriate control signals UL_GAIN_1,UL_GAIN_2 and UL_GAIN_M illustrated respectively by reference numerals118, 120 and 122 in FIG. 5 may be directed to the remote unitillustrated in FIG. 5 by either the distribution unit 28 or a masterunit 22. The gains then provided by the circuits 124, 126 and 128 areapplied to the specific subband signals associated with the subbands 58,60 and 64.

In accordance with another aspect of the invention, utilization ofseparate muting circuitry for a remote unit, or a specific band orsubband may not be necessary if gain circuitry is implemented for thatspecific remote unit, band or subband. If it is determined that aparticular remote unit or band/subband is not handling uplink trafficsignals, such as uplink signals from a mobile unit, the specific uplinkgain for the adjustable gain circuitry of the remote unit might be setto zero for a particular remote unit or selected bands or subbands inorder to mute that remote unit or band or subband.

Referring to FIG. 3B, remote unit circuitry is illustrated wherein amuting circuit is not implemented, but rather the adjustable gaincircuitry 49 is utilized to effectively create a mute condition at theremote unit 14 b. That is, based upon the MUTE_STATUS signal directed toa distribution unit or master unit, the gain circuitry 49 may beappropriately adjusted utilizing a UL_GAIN signal 51 to set the uplinkgain for the remote unit 14 b to zero or effectively low enough toestablish a muting condition (mute status) for that remote unit 14 b.Similarly, the muting circuitry might be eliminated with respect to theband and subband circuits of FIGS. 4 and 5 so that muting is handledprimarily through control of the adjustable gain circuitry in thosecircuits.

While various of the illustrated examples show the signal detection andmuting and gain adjustment handled in the remote units, in alternativeembodiments, subbanding, signal detection, and muting may occur in theremote unit 14 or alternatively in distribution unit 28. Additionally,in other embodiments, the dividing the incoming signals into bandsand/or subbands may be performed in the remote unit 14 while the mutingand detection for the remote or bands/subbands may be performed eitherin the distribution unit 28 or even at the master unit 22. Thesubbanding of the signals and detection to determine muting may occur inany of the components of the DAS 10 as long as they take place prior tothe various remote and band/subband signals being combined in the uplinkdirection for transmission to the base station 12.

In accordance with the invention, the uplink gain within a distributedantenna system or other signal repeating system is dynamically adjustedbased upon monitoring a noise condition of the distributed antennasystem. More specifically, the invention monitors the activity level(mobile device traffic) and MUTE_STATUS (mute status/active status)associated with remote units in the system. The determination ofactivity level and status may be made based upon the remote unit itself,or with respect to a band or subband that is handled by the remote unit.As the MUTE_STATUS of the remote unit and/or the bands and subbands ofthe remote unit indicate that the remote unit or the bands/subbands aremute status (i.e., no activity or uplink signals from mobile devices)the uplink gain within the system is dynamically increased. The uplinkgain might be increased at the master unit, at a distribution unit, orindividually at the remote units. Furthermore, the uplink gain might bedynamically adjusted based upon the specific bands or subbands of aremote unit. The dynamic adjustment in the uplink gain may occur inincrements. The increments may be related to the number of specificelements that are mute status in the system, including the remote unit,a band of a remote unit or a subband of a remote unit. Alternatively,the increments might be determined by the groups of elements (e.g., 10remote units) that are mute status or other suitable criteria associatedwith the muted elements in order to provide the incremental dynamicadjustment in the uplink gain. As discussed with the various examplesset forth herein, as more mute status (less active status) elements inthe system are detected, the uplink gain is dynamically increased. Itwill be understood as well, that as activity is detected in a remoteunit or band/subband and the specific element is unmuted or activestatus, the uplink gain is dynamically decreased in order to ensure asuitable noise floor for the overall system so that it does notdetrimentally affect the noise floor of the base station. The dynamicincrease of the uplink gain might be limited by an upper limit asdetermined for the system, while the dynamic decrease of the uplink gainmight be constrained by a lower limit.

For example, if an overall system includes 100 remotes and 90 of the 100remotes are muted, the noise floor of the overall system may drop 10 dB.Accordingly, the uplink gain for the system might be dynamicallyadjusted to increase 10 dB in total and still remain at a suitable levelso as not to detrimentally affect the base station's noise floor. Oncethe uplink gain has been increased, the mobile units 16 can, in turn,reduce their gain by roughly the same amount of uplink gain increase atthe signal repeating system or DAS and still maintain the samecarrier-to-noise carrier ratio (C/N) at the base station.

While the present invention has been illustrated by a description of oneor more embodiments thereof and while these embodiments have beendescribed in considerable detail, they are not intended to restrict orin any way limit the scope of the appended claims to such detail.Additional advantages and modifications will readily appear to thoseskilled in the art. The invention in its broader aspects is thereforenot limited to the specific details, representative apparatus andmethod, and illustrative examples shown and described. Accordingly,departures may be made from such details without departing from thescope of the general inventive concept.

What is claimed is:
 1. A system comprising: circuitry configured to:communicate with a base station; and adjust an uplink gain applied touplink signals communicated from the system to the base station based onan evaluation of (1) a noise contribution from the system that ispresented to the base station and (2) a receive noise floor for the basestation.
 2. The system of claim 1, wherein the circuitry is configuredto wirelessly communicate with the base station.
 3. The system of claim1, wherein the circuitry is further configured to: adjust the uplinkgain applied to the uplink signals to establish a target noise floor forthe noise contribution from the system.
 4. The system of claim 3,wherein the circuitry is further configured to: evaluate a path lossfrom the system to the base station to establish the target noise floor.5. The system of claim 1, wherein the circuitry is further configuredto: adjust the uplink gain to make the noise contribution from thesystem lower than the receive noise floor of the base station.
 6. Thesystem of claim 5, wherein the circuitry is further configured to:adjust the uplink gain to make at least one of (1) the noisecontribution from the system and (2) the noise contribution from thesystem plus the path loss to the base station lower than the receivenoise floor of the base station by a threshold amount.
 7. The system ofclaim 1, wherein the circuitry is further configured to: evaluate a pathloss from the system to the base station; and adjust the uplink gain tomake the noise contribution from the system plus the path loss to thebase station lower than the receive noise floor of the base station. 8.The system of claim 1, wherein the system includes: a master unit; and aplurality of remote units communicatively coupled to the master unit. 9.The system of claim 1, wherein the circuitry is further configured to:reduce the uplink noise in the system by attenuating or muting signalswithin the system.
 10. The system of claim 1, wherein the circuitry isconfigured to adjust the uplink gain applied to uplink signalscommunicated from the system to the base station by: increasing theuplink gain in response to a decrease in the noise floor of the system;and decreasing the uplink gain in response to an increase in the noisefloor of the system.
 11. A system, comprising: a repeater configured tocommunicate with a base station; circuitry configured to: adjust a gainapplied to uplink signals communicated from the system to the basestation based on (1) a noise contribution from the system that ispresented to the base station; and (2) a receive noise floor for thebase station.
 12. The system of claim 11, wherein the repeater isconfigured to wirelessly communicate with the base station.
 13. Thesystem of claim 12, wherein the circuitry is configured to at least oneof: adjust the uplink gain that is applied to uplink signals toestablish a target noise floor for the noise contribution from thesystem; evaluate a path loss from the system to the base station toestablish the target noise floor; and adjust the uplink gain to make thenoise contribution from the system lower than the receive noise floor ofthe base station.
 14. The system of claim 12, wherein the systemincludes a master unit communicatively coupled to a plurality of remoteunits.
 15. The system of claim 12, wherein the circuitry is furtherconfigured to: reduce the uplink noise in the system by attenuating ormuting signals within the system.
 16. A method of controlling uplinksignal power in a system communicating with a base station, the methodcomprising: adjusting an uplink gain applied to uplink signalscommunicated from the system to the base station based on (1) a noisecontribution from the system that is presented to the base station; and(2) a receive noise floor for the base station.
 17. The method of claim16, further comprising at least one of: adjusting the uplink gain thatis applied to uplink signals to establish a target noise floor for thenoise contribution from the system; evaluating a path loss from thesystem to the base station to establish the target noise floor; andadjusting the uplink gain to make the noise contribution from the systemlower than the receive noise floor of the base station.
 18. The methodof claim 16, further comprising: adjusting the uplink gain to make thenoise contribution from the system lower than the receive noise floor ofthe base station by a threshold amount.
 19. The method of claim 16,further comprising: evaluating a path loss from the system to the basestation; and adjusting the uplink gain to make the noise contributionfrom the system plus the path loss to the base station lower than thereceive noise floor of the base station by a threshold amount.
 20. Themethod of claim 16, further comprising: reducing the uplink noise in thesystem by attenuating or muting signals within the system.